西藏冈底斯中段桑桑花岗质岩体锆石U-Pb年龄与Hf同位素组成及其对岩石成因和构造演化的制约

以西藏冈底斯中段西侧桑桑花岗质岩体为对象,进行了系统的年代学、元素地球化学和锆石Hf同位素组成研究,据此阐明了岩体成因,并探讨了其构造意义。锆石LA-ICP-MS U-Pb定年表明,桑桑花岗质岩体的成岩年龄为49~54 Ma。化学组成上,岩体具有亚碱、准铝、贫磷的特征(A/NKC1.10,P_2O_50.20%),属钙碱性I型花岗岩类。岩体富Cs、Rb、Ba、Th、U、K、Pb和轻稀土,贫Nb、Ta、P与Ti,表现出弧岩浆岩的地球化学特征。岩体的锆石εHf(t)值变化较大,散布于正值与负值之间(=-4.24~+5.49),指示其形成存在不同来源物质的贡献。综合分析表明,桑桑花岗质岩体起源于初生地壳的部分熔融,但在成岩过程中有古老地壳组分的参与。结合区域地质背景,笔者认为这一古老地壳组分最可能来自印亚碰撞过程中俯冲下插的印度地壳,由此说明印度-欧亚大陆碰撞的起始时间应早于54 Ma。     

准噶尔盆地乌夏前陆冲断带沉降史与沉积响应研究

针对前陆冲断带的特殊构造位置及沉积特征的复杂性,本文在地层剥蚀厚度恢复和层序划分的基础上,通过对准噶尔盆地西缘乌夏前陆冲断带沉降史分析,在海西运动晚期准噶尔地块与西伯利亚板块发生碰撞挤压,形成一系列冲断推覆构造,前缘岩石圈挠曲下陷发育周缘前陆盆地,并夹杂大规模的短暂伸展火山喷发活动,接受了巨厚的二叠系沉积层序;随着板块俯冲在二叠纪末的逐渐消亡,三叠纪进入印支期陆内坳陷继承性挤压活动阶段,周边受南北向挤压和左旋构造应力场影响,前陆冲断带古断裂再次逆冲,哈拉阿拉特山急剧抬升,后缘和什托洛盖盆地形成;进入侏罗纪—白垩纪(燕山运动早中期),为陆内坳陷的填充消亡阶段,但有继承性活动,构造活动强度较二叠纪大为减弱,在燕山运动Ⅲ幕晚期最终被覆盖定型。整个过程受地体碰撞和板内挤压影响,冲断带发生幕式构造活动,从而导致盆地沉降也发生幕式变化,而且冲断带每次挤压逆冲均导致相应的沉降和沉积物充填,并直接控制前陆盆地和陆内坳陷的沉积充填特征。     

中太平洋海山区富钴结壳构造与地球化学特征及意义

为了释读蕴藏在富钴结壳中的环境变化信息,运用电子探针技术对中太平洋海山CXD05结壳进行了详细的构造和地球化学研究.结果表明:1)CXD05结壳约从19.4 Ma BP(早中新世)开始发育,从基部至顶部依次发育了斑杂构造、柱状构造和纹层构造;2)结壳中亲氧元素和碎屑组分从老至新发生规律性变化.结壳构造序列反映了其生长过程中海洋动力环境能量由高到低的变化;而壳层亲氧元素和碎屑组分的变化则记录了海水的氧化程度和风尘影响强度的变化.     

Ophiuroid fauna of cobalt-rich crust seamounts in the Northwest Pacific Ocean

Seamounts are vulnerable ecosystems in the deep sea and can be heavily impacted by human activities, such as bottom fishing and deep-sea mining. The species composition and distribution patterns of benthic fauna is key information for the designation of marine protected areas and environmental management plans. Three contracts for cobalt-rich crust exploration have been granted to China, Japan and Korea in the Northwest Pacific Ocean by the International Seabed Authority. However, our knowledge ...     

南秦岭东部新元古代埃达克质岩的发现及其地质意义

秦岭造山带是一条复合型大陆碰撞造山带,存在若干新元古代构造岩浆事件的遗迹,它们对深化认识南北秦岭汇聚-碰撞过程和Rodinia超大陆聚合具有重要意义。本文对南秦岭东部豆腐尖岩体英云闪长岩开展LA-ICP-MS锆石U-Pb年代学和全岩主微量元素地球化学研究。代表性样品的²⁰⁶Pb/²³⁸U加权平均年龄为860.7±6.0Ma,表明其形成时代为新元古代。岩石地球化学特征表现为高SiO₂(62.41%～68.89%)、高Al₂O₃(15.33%～17.33%),富Na₂O(4.23%～5.80%)和高Na₂O/K₂O比值(1.11～2.41),富Sr(>400×10^-6),低MgO(0.55%～2.08%),低Y(7.40×10^-6～18.20×10^-6)、Yb(0.63×10^-6～1.62×10^-6),...     

北天山东段康古尔塔格碰撞构造

塔里木板块和准噶尔板块间的康古尔塔格带是发育在北天山东部地区的晚古生代碰撞构造，本文对该碰撞造山带在形成和地质演化过程中的构造变动、岩浆作用和沉积作用做了较详细的论述，并对该碰撞构造的碰撞时代、碰撞单元和碰撞标志进行了探讨，尝试性提出了其碰撞的４个阶段．     

Flux monitoring at 327 MHz during SL9-Jupiter collision

Jupiter flux at 327 MHz was monitored using the Ooty radio telescope from July 12th to July 29th during the collision of comet Shoemaker-Levi 9 with Jupiter. Flux was found to increase steadily from July 17th to July 26th by ∼ 2–5 Jy, after which it declined to its pre-event value. The comparison of 327 MHz observations with those at 840 MHz and 2240 MHz indicates that the enhancement was mainly due to the increased synchrotron emission and the contribution of thermal emission was very small at metric-decimetric frequencies. The enhancement in radio emission was found to be more at 840 MHz than at 327 or 2240 MHz. The steepening of the spectrum between 327 and 840 MHz as well as between 2240 and 840 MHz was also noted.     

Second Species Periodic Orbits of the Elliptic 3 Body Problem

We consider the plane restricted elliptic 3 body problem with small mass ratio and small eccentricity and prove the existence of many periodic orbits shadowing chains of collision orbits of the Kepler problem. Such periodic orbits were first studied by Poincaré for the non-restricted 3 body problem. Poincaré called them second species solutions.     

电感耦合等离子体质谱法测定高纯铟中铁

建立了基于碰撞/反应池（CCT）技术的电感耦合等离子体质谱法（ICP-MS）测定高纯铟中铁元素的方法。在CCT模式下,有效地消除了如⁴⁰Ar¹⁶O等多原子离子对待测元素的干扰,不分离基体就可直接测定铁。方法检出限为0.06ng/mL,精密度（RSD,n=11）<8%,回收率为94.0%～102.1%。方法与现行的国家标准分析方法相比,操作简便、高效。     

Contribution of syncollisional felsic magmatism to continental crust growth: A case study of the Paleogene Linzizong volcanic Succession in southern Tibet

The Linzizong volcanic succession (~ 65–45 Ma) and the coeval batholiths (~ 60−40 Ma) of andesitic to rhyolitic composition represent a magmatic response to the India–Asia continental collision that began at ~ 70–65 Ma and ended at ~ 45–40 Ma with convergence continuing to present. These syncollisional felsic magmatic rocks are widely distributed along much of the > 1500 km long Gangdese Belt immediately north of the India–Asia suture (Yarlung–Zangbo) in southern Tibet. Our study of the Linzizong volcanic rocks from the Linzhou Basin (near Lhasa) suggests that syncollisional felsic magmatism may in fact account for much of the net contribution to continental crust growth. These volcanic rocks show a first-order temporal change from the andesitic lower Dianzhong Formation (64.4–60.6 Ma), to the dacitic middle Nianbo Formation (~ 54 Ma), and to the rhyolitic upper Pana Formation (48.7–43.9 Ma). The three formations show no systematic but overlapping Nd–Sr isotope variations. The isotopically depleted samples with ε_Nd(t) > 0 indicate that their primary sources are of mantle origin. The best source candidate in the broad context of Tethyan ocean closing and India–Asia collision is the remaining part of the Tethyan ocean crust. This ocean crust melts when reaching its hydrous solidus during and soon after the collision in the amphibolite facies, producing andesitic melts parental to the Linzizong volcanic succession (and the coeval batholiths) with inherited mantle isotopic signatures. Ilmenite as a residual phase (plus the effect of residual amphibole) of amphibolite melting accounts for the depletion of Nb, Ta and Ti in the melt. The effect of ocean crust alteration plus involvement of mature crustal materials (e.g., recycled terrigeneous sediments) enhances the abundances of Ba, Rb, Th, U, K and Pb in the melt, thus giving the rocks an “arc-like” geochemical signature. Residual amphibole that possesses super-chondritic Nb/Ta ratio explains the sub-chondritic Nb/Ta ratio in the melt; residual plagioclase explains the slightly depleted, not enriched, Sr (and Eu) in the melt, typical of continental crust. These observations and reasoning plus the remarkable compositional similarity between the andesitic lower Dianzhong Formation and the model bulk continental crust corroborates our proposal that continental collision zones may be sites of net crustal growth (juvenile crust) through process of syncollisional felsic magmatism. While these interpretations are reasonable in terms of straightforward petrology, geochemistry and tectonics, they require further testing.